Recyclable and reformable epoxy resins based on dynamic covalent bonds – Present, past, and future

Epoxy resins, as a typical class of thermosetting polymers, have widespread industrial applications such as adhesives, coatings, electronic encapsulants, and polymer matrices for advanced composites, owing to their excellent mechanical performance, adhesive capacity, dimensional stability, heat, and...

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Published in	Polymer testing Vol. 105; p. 107420
Main Authors	Memon, Hafeezullah, Wei, Yi, Zhu, Chengyan
Format	Journal Article
Language	English
Published	Elsevier Ltd 01.01.2022 Elsevier
Subjects	Dynamic bond Epoxy Recycling Vitrimers Dynamic bond Recycling Epoxy Vitrimers
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Abstract	Epoxy resins, as a typical class of thermosetting polymers, have widespread industrial applications such as adhesives, coatings, electronic encapsulants, and polymer matrices for advanced composites, owing to their excellent mechanical performance, adhesive capacity, dimensional stability, heat, and chemical resistance. However, conventional epoxy resins cannot be reprocessed, repaired, or recycled due to their permanent crosslinked structures, making it a long-standing challenge to process and recycle the ever-increasing epoxy and epoxy-based composite similar to thermoplastics. Therefore, both economic and environmental factors are driving the development of reformable and recyclable epoxy resins. In this paper, various such epoxy vitrimers containing dynamic covalent bonds are reviewed. Future potentials of these epoxy vitrimers are also discussed. •Summarizes recent development in the field of recyclable epoxy based on dynamic covalent bonds.•Suggests potential research subjects as well as potential future application.•Provides a critical discussion on the progress of recyclable and reformable epoxy.
AbstractList	Epoxy resins, as a typical class of thermosetting polymers, have widespread industrial applications such as adhesives, coatings, electronic encapsulants, and polymer matrices for advanced composites, owing to their excellent mechanical performance, adhesive capacity, dimensional stability, heat, and chemical resistance. However, conventional epoxy resins cannot be reprocessed, repaired, or recycled due to their permanent crosslinked structures, making it a long-standing challenge to process and recycle the ever-increasing epoxy and epoxy-based composite similar to thermoplastics. Therefore, both economic and environmental factors are driving the development of reformable and recyclable epoxy resins. In this paper, various such epoxy vitrimers containing dynamic covalent bonds are reviewed. Future potentials of these epoxy vitrimers are also discussed. Epoxy resins, as a typical class of thermosetting polymers, have widespread industrial applications such as adhesives, coatings, electronic encapsulants, and polymer matrices for advanced composites, owing to their excellent mechanical performance, adhesive capacity, dimensional stability, heat, and chemical resistance. However, conventional epoxy resins cannot be reprocessed, repaired, or recycled due to their permanent crosslinked structures, making it a long-standing challenge to process and recycle the ever-increasing epoxy and epoxy-based composite similar to thermoplastics. Therefore, both economic and environmental factors are driving the development of reformable and recyclable epoxy resins. In this paper, various such epoxy vitrimers containing dynamic covalent bonds are reviewed. Future potentials of these epoxy vitrimers are also discussed. •Summarizes recent development in the field of recyclable epoxy based on dynamic covalent bonds.•Suggests potential research subjects as well as potential future application.•Provides a critical discussion on the progress of recyclable and reformable epoxy.
ArticleNumber	107420
Author	Memon, Hafeezullah Wei, Yi Zhu, Chengyan
Author_xml	– sequence: 1 givenname: Hafeezullah orcidid: 0000-0001-5985-5394 surname: Memon fullname: Memon, Hafeezullah email: hm@zstu.edu.cn organization: College of Textile Science and Engineering, International Institute of Silk, Zhejiang Sci-Tech University, Hangzhou, 310018, China – sequence: 2 givenname: Yi orcidid: 0000-0001-5177-4207 surname: Wei fullname: Wei, Yi email: weiy@dhu.edu.cn organization: Center for Civil Aviation Composites, Donghua University, 2999 North Renmin Road, Shanghai, 201620, China – sequence: 3 givenname: Chengyan surname: Zhu fullname: Zhu, Chengyan email: cyzhu@zstu.edu.cn organization: College of Textile Science and Engineering, International Institute of Silk, Zhejiang Sci-Tech University, Hangzhou, 310018, China
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